In this paper, we consider a cognitive indoor visible light communications
(VLC) system, comprised of multiple access points serving primary and secondary
users through the orthogonal frequency division multiple access method. A
cognitive lighting cell is divided into two non-overlapping regions that
distinguish the primary and secondary users based on the region they are
located in. Under the assumption of equal-power allocation among subcarriers,
each region is defined in terms of its physical area and the number of
allocated subcarriers within that region. In this paper, we provide the
lighting cell design with cognitive constraints that guarantee fulfilling
certain illumination, user mobility, and handover requirements in each cell. We
further argue that, under some conditions, a careful assignment of the
subcarriers in each region can mitigate the co-channel interference in the
overlapping areas of adjacent cells. Numerical results depict the influence of
different system parameters, such as user density, on defining both regions.
Finally, a realistic example is implemented to assess the performance of the
proposed scheme via Monte Carlo simulations
